JP2016128833A - Radio watch - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio watch allowing a user to understand the effectiveness of a leap second correction value.SOLUTION: A radio watch 1 receives a signal including time information from a satellite and corrects the time. The radio watch includes: storing means for storing a leap second correction value used for correction of the leap second for the time information and information related to the effective period of the leap second correction value; determining means for determining whether the leap second correction value stored in the storing means is effective by using the information related to the effective period; and determination result displaying means for displaying the determination result of the determining means.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a radio timepiece that corrects time based on a signal received from a satellite.

  There is known a radio timepiece that receives a radio wave including time information from an external time information supply source and corrects the time. As one type of such a radio timepiece, a radio timepiece that corrects the time using a signal received from a satellite such as a GPS (Global Positioning System) satellite has been studied (see, for example, Patent Documents 1 and 2).

JP 2009-168620 A JP 2008-145287 A

  In the above-described radio timepiece, it may be necessary to correct leap seconds in order to obtain time in accordance with Coordinated Universal Time (UTC) from time information included in a received signal. If the signal transmitted by the satellite includes information on such leap seconds, the radio timepiece may receive the information on leap seconds and correct the time information. However, in the case of a GPS satellite, for example, information related to leap seconds is not transmitted as frequently as time information, and therefore, it is possible that information regarding leap seconds cannot be received. In addition, due to hardware restrictions, it may be impossible to implement a function for receiving such leap second information in addition to time information.

  The present invention has been made in view of the above problems, and one of its purposes is to provide a radio timepiece that allows a user to grasp the effectiveness of a leap second correction value.

  The radio timepiece according to the present invention is a radio timepiece that receives a signal including time information from a satellite and corrects the time, and includes a leap second correction value used for correcting a leap second with respect to the time information, and the leap second correction value. Storage means for storing information on the expiration date of the data, determination means for determining whether the leap second correction value stored in the storage means is valid using the information on the expiration date, and the determination means And a determination result display means for displaying the determination result.

  Further, leap second display means for displaying a numerical value corresponding to the leap second correction value stored in the storage means may be further included.

  The signal from the satellite includes leap second adjustment advance notice information, receives a signal from the satellite including the leap second adjustment advance notice information, and manages information related to the expiration date based on the received signal. A first management means may be further included.

  Moreover, it is good also as a 2nd management means which determines whether June or December passed and manages the information regarding the said expiration date based on a determination result.

  Moreover, it is good also as a 3rd management means which determines whether the 1st of every month has arrived and manages the information regarding the said expiration date based on a determination result.

  The signal from the satellite includes information related to the leap second correction value, and the radio timepiece receives a signal from the satellite including information related to the leap second correction value, and the signal according to the received signal According to the received instruction operation, the leap second information receiving means for changing the leap second correction value stored in the storage means, the instruction receiving means for receiving an instruction operation for changing the leap second correction value from the user, A leap second correction value changing means for changing the leap second correction value stored in the storage means, and whether the leap second correction value stored in the storage means has been changed in accordance with a signal from the satellite, or the received instruction operation And changing means for determining whether the leap second correction value stored in the storage means has been changed, and changing the management method of the information related to the expiration date based on the determination result.

  According to the radio-controlled timepiece according to the present invention, it is possible for the user to grasp the effectiveness of the leap second correction value.

It is a top view which shows the external appearance of the radio timepiece concerning a 1st embodiment of the present invention. It is a block diagram showing the internal configuration of the radio timepiece according to the first embodiment of the present invention. It is a schematic diagram which shows the structure of the satellite signal transmitted from a GPS satellite. It is a functional block diagram which shows the function which the radio timepiece concerning a 1st embodiment of the present invention realizes. It is a state transition diagram of the radio timepiece according to the first embodiment of the present invention. It is explanatory drawing which shows the change of a display state when the radio timepiece which concerns on 1st Embodiment of this invention performs the update process of leap second. It is a figure which shows the example of a display of the numerical value according to the leap second correction value. It is a state transition diagram of the radio timepiece concerning a 2nd embodiment of the present invention. It is explanatory drawing which shows the display content at the time of the radio timepiece which concerns on 2nd Embodiment of this invention performing the update process of leap second. It is a figure which shows another example of a display of the numerical value according to the leap second correction value. It is a figure which shows another example of a display of the numerical value according to the leap second correction value. It is a figure which shows another example of a display of the numerical value according to the leap second correction value. It is a figure which shows the example of a display of the expiration date of a leap second correction value. It is a figure which shows the example of a display of the information relevant to a leap second correction value.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following, a case where the radio timepiece according to the embodiment of the present invention is a wristwatch will be described as an example.

[First Embodiment]
First, the radio timepiece according to the first embodiment of the present invention will be described. The radio timepiece 1 according to the present embodiment receives a satellite signal including time information transmitted by a satellite, and corrects the time information using the received satellite signal. FIG. 1 is a plan view showing an appearance of a radio timepiece 1 according to the present embodiment. FIG. 2 is a block diagram showing the internal configuration of the radio timepiece 1. As shown in the figure, the radio-controlled timepiece 1 includes an antenna 10, a receiving circuit 20, a control circuit 30, a power source 40, a solar cell 41, a drive mechanism 50, a time display unit 51, and an operation unit 60. , Including.

  The antenna 10 receives a satellite signal transmitted from a satellite. In the present embodiment, the antenna 10 receives a radio wave having a frequency of about 1.6 GHz transmitted from a GPS (Global Positioning System) satellite. GPS is a kind of satellite positioning system, and is realized by a plurality of GPS satellites orbiting around the earth. Each of these GPS satellites is equipped with a high-accuracy atomic clock, and periodically transmits a satellite signal including time information measured by the atomic clock. Hereinafter, the time indicated by the time information included in the satellite signal is referred to as GPS time.

  The receiving circuit 20 decodes the satellite signal received by the antenna 10 and outputs a bit string (received data) indicating the contents of the satellite signal obtained as a result of the decoding. Specifically, the receiving circuit 20 includes a high frequency circuit (RF circuit) 21 and a decoding circuit 22.

  The high-frequency circuit 21 is an integrated circuit that operates at a high frequency, and amplifies and detects an analog signal received by the antenna 10 to convert it into a baseband signal. The decode circuit 22 is an integrated circuit that performs baseband processing, decodes the baseband signal output from the high-frequency circuit 21, generates a bit string indicating the content of data received from a GPS satellite, and outputs the bit string to the control circuit 30. Output.

  The control circuit 30 is a microcomputer or the like, and includes a calculation unit 31, a ROM (Read Only Memory) 32, a RAM (Random Access Memory) 33, an RTC (Real Time Clock) 34, a motor drive circuit 35, It is comprised including.

  The calculation unit 31 performs various types of information processing according to programs stored in the ROM 32. Details of the processing executed by the calculation unit 31 in the present embodiment will be described later. The RAM 33 functions as a work memory of the calculation unit 31 and data to be processed by the calculation unit 31 is written. In particular, in this embodiment, a bit string (received data) representing the contents of the satellite signal received by the receiving circuit 20 is sequentially written in the buffer area in the RAM 33. Further, the leap second correction value LS used for correcting the time information is stored in the RAM 33. The RTC 34 supplies a clock signal used for timing in the radio timepiece 1. In the radio timepiece 1 according to the present embodiment, the calculation unit 31 corrects the internal time measured by the signal supplied from the RTC 34 based on the satellite signal received by the reception circuit 20, and displays the time on the time display unit 51. The time to be displayed (display time) is determined. Further, the motor drive circuit 35 outputs a drive signal for driving a motor included in the drive mechanism 50 described later according to the determined display time. As a result, the display time generated by the control circuit 30 is displayed on the time display unit 51.

  The power source 40 is configured to include a power storage device such as a secondary battery, and stores the power generated by the solar cell 41. Then, the accumulated power is supplied to the receiving circuit 20 and the control circuit 30. In particular, a switch 42 is provided in the middle of the power supply path from the power supply 40 to the receiving circuit 20, and the on / off of the switch 42 is switched by a control signal output from the control circuit 30. That is, the control circuit 30 can control the operation timing of the receiving circuit 20 by switching the switch 42 on and off. The receiving circuit 20 operates only while power is supplied from the power supply 40 via the switch 42, and decodes the satellite signal received by the antenna 10 during that time.

  The solar cell 41 is disposed under the dial 53, generates power using external light such as sunlight irradiated on the radio timepiece 1, and supplies the generated power to the power supply 40.

  The drive mechanism 50 includes a step motor that operates in accordance with the drive signal output from the motor drive circuit 35 described above and a train wheel, and the train wheel transmits the rotation of the step motor, thereby indicating the pointer. 52 is rotated. The time display unit 51 includes a pointer 52 and a dial 53. The pointer 52 includes an hour hand 52a, a minute hand 52b, and a second hand 52c, and when the pointer 52 rotates on the dial 53, the current time is displayed. On the dial 53, as shown in FIG. 1, not only a scale for displaying the time, but also a marker for indicating to the user whether the leap second correction value LS, which will be described later, is valid / invalid or whether or not the time information has been successfully received. Is also displayed. Display examples using these markers will be described later.

  The operation unit 60 receives an operation by the user of the radio timepiece 1 and outputs the operation content to the control circuit 30. Specifically, in the present embodiment, the operation unit 60 includes two operation buttons, a first operation button S1 and a second operation button S2, and a crown S3, as shown in FIG. The control circuit 30 executes processing such as update of a leap second correction value LS and reception of a satellite signal, which will be described later, according to the contents of the operation input received by the operation unit 60. Thus, the user can cause the radio-controlled timepiece 1 to perform operations such as leap second correction by operating the operation unit 60.

  Here, the configuration of the satellite signal transmitted by the GPS satellite will be described. FIG. 3 is a schematic diagram showing a configuration of a satellite signal (navigation data) transmitted from a GPS satellite. As shown in the figure, each GPS satellite repeatedly transmits navigation data having a total of 25 frames (pages) as one set. Each frame includes a signal for 30 seconds, and the GPS satellite transmits a signal of 25 frames in a cycle of 12.5 minutes. Further, each frame is composed of five subframes. Since one frame is 30 seconds, one subframe corresponds to a signal for 6 seconds. Further, one subframe is composed of 10 words and includes information of 30 bits per word and 300 bits per one subframe.

  The head word (first word) of each subframe is called a TLM (TeLeMetry word), and the head portion (that is, the head portion of the entire subframe) includes a preamble indicating the start position of the subframe. . Further, the second word (second word) of each subframe is called HOW (HandOver Word), and the head portion thereof includes time information called TOW (Time Of Week). This TOW is time information indicating GPS time starting from the beginning of the week (Sunday 0:00 am). The radio timepiece 1 receives the TOW data from one or a plurality of GPS satellites, and can combine the information with the week number WN information to know the GPS time measured by the GPS satellites. The week number WN is information indicating the number of the week to which the time represented by TOW belongs, and is counted up once every week at 0:00 am on Sunday. Information of the week number WN is stored in the first subframe of each frame and transmitted from a GPS satellite.

  The radio timepiece 1 can acquire the time information transmitted by the GPS satellite by receiving the TOW included in any of the subframes. However, the GPS time indicated by this time information has a difference of integer seconds caused by leap seconds with respect to Coordinated Universal Time. Specifically, the GPS time is offset from Coordinated Universal Time by the leap second accumulated since the first launch of the GPS satellite (1980). Therefore, the radio timepiece 1 needs to correct the GPS time obtained from the GPS satellite to a time based on the Coordinated Universal Time using leap second information.

  Information on leap seconds necessary for this correction is also periodically transmitted from GPS satellites. Specifically, leap second information is included in the fourth subframe of the frame on the 18th page among the satellite signals of all 25 frames transmitted by the GPS satellite. The last 5 words of the subframe (that is, the 151st bit after the first) are information on the Coordinated Universal Time, and the information on the Coordinated Universal Time is included in the GPS time for the leap second adjustment. Information of an integer value (hereinafter referred to as leap second correction value LS) to be corrected. Since the leap second correction value LS is included in only one subframe of the entire navigation data, the leap second correction value LS is transmitted from the GPS satellite at a cycle of once every 12.5 minutes. The radio timepiece 1 according to the present embodiment corrects leap seconds by extracting leap second correction values LS included in satellite signals received from GPS satellites, but receives information on leap second correction values LS from GPS satellites. As an alternative means when this is not possible, a function is provided that allows the user to manually change the leap second correction value LS.

  The subframe including the leap second correction value LS includes information on the scheduled date and time (leap second adjustment advance notice information) for the next leap second adjustment, along with the leap second correction value LS. This information is updated when the next leap second adjustment scheduled execution date is determined, and information indicating the date and time when the previous leap second adjustment was performed while the next leap second adjustment execution timing has not yet been determined. It has become. If the leap second adjustment notice information indicates a future date and time, it can be seen that the leap second correction value LS is not changed until the date and time arrives.

  Hereinafter, a specific example of processing executed by the calculation unit 31 of the control circuit 30 in the present embodiment will be described. As shown in FIG. 4, the arithmetic unit 31 functionally executes a program stored in the ROM 32 to functionally include a satellite signal receiving unit 31a, a leap second information management unit 31b, and a time correction unit 31c. Realize.

  The satellite signal receiving unit 31a receives the satellite signal transmitted from the GPS satellite, thereby acquiring the TOW and week number WN data included therein. The satellite signal receiving unit 31a may periodically execute such time information acquisition processing, or may execute these processing in response to an instruction operation on the operation unit 60 by the user. Further, in the present embodiment, the satellite signal receiving unit 31a attempts to receive a subframe including the leap second correction value LS at a predetermined timing. If reception is successful, the leap second correction value LS is extracted from the received data and stored in the RAM 33.

  The leap second information management unit 31 b manages the leap second correction value LS stored in the RAM 33. Specifically, the RAM 33 stores information on the expiration date of the leap second correction value LS (leap second expiration date information) together with information on the leap second correction value LS, and the leap second information management unit 31b stores this information. Is used to determine whether the leap second correction value LS stored in the RAM 33 is valid (that is, whether the leap second correction value LS has expired). Furthermore, if it is determined that the expiration date of the leap second correction value LS has expired, the leap second information management unit 31b performs a manual update process of the leap second correction value LS according to a user instruction. That is, the leap second information management unit 31b is stored in the RAM 33 in response to an instruction operation on the operation unit 60 by the user when the expiration date of the leap second correction value LS stored in the RAM 33 has expired. The current leap second correction value LS is displayed and updated. A specific example of the leap second correction value LS update process executed by the leap second information management unit 31b will be described later.

  The time correction unit 31 c is timed inside the radio timepiece 1 using the GPS time information received from the GPS satellite by the satellite signal reception unit 31 a and the leap second correction value LS stored in the RAM 33. Correct the internal time. Specifically, the time correction unit 31c first calculates time information based on Coordinated Universal Time by adding a leap second correction value LS to the GPS time. Then, the internal time measured in the control circuit 30 is corrected so as to coincide with the coordinated universal time. The internal time information of the radio timepiece 1 to be corrected by the time correction unit 31c is stored in the RAM 33 and updated according to the clock signal supplied from the RTC 34. Here, the time correction unit 31c may perform time correction using the leap second correction value LS even when the expiration date of the leap second correction value LS has expired. Even if the expiration date set inside the radio-controlled timepiece 1 has expired, it is based on the Coordinated Universal Time using the leap second correction value LS stored in the RAM 33, unless a new leap second adjustment is actually performed. This is because the time can be calculated.

  Hereinafter, the expiration date of the leap second correction value LS managed by the leap second information management unit 31b will be described. The leap second adjustment for Coordinated Universal Time is to be implemented on the last day of each month in Coordinated Universal Time. Therefore, for example, when the leap second correction value LS is manually updated, the leap second information management unit 31b stores the leap second correction value LS currently stored at least until the last day of the month when the update is performed. Judged as valid. In addition, leap second adjustment is preferentially carried out on the last day of June and the last day of December, and is currently not carried out on other days. Therefore, after the leap second correction value LS is updated, the leap second information management unit 31b may determine that the leap second correction value LS is valid until the next end of June or the end of December. Not limited to this, it may be determined that the leap second correction value LS is valid until the predetermined period elapses after the leap second correction value LS is updated, or a predetermined date and time arrives. It is good also as judging that it is effective.

  Specifically, as a method for managing the expiration date of the leap second correction value LS, for example, when the leap second correction value LS is manually updated, the leap second information management unit 31b sets the leap second validity flag to “ In addition to updating to a value indicating “valid”, information indicating how many months the updated leap second correction value LS is valid (information on the expiration date) is updated. In this example, the leap second validity flag and the information on the validity period month are used as the leap second validity period information. As an example, when the leap second correction value LS is updated in February 2010, the leap second information management unit 31b is the month in which the last day comes first after the update date in June and December 2010 Set June as the expiration month. Thereafter, when the first day of every month arrives, the leap second information management unit 31b compares the information on the expiration date with the information on the internal time based on the Coordinated Universal Time held in the RAM 33, and the expiration month has passed. Determine whether or not. In the above-described example, it is determined that the expiry date of the leap second correction value LS has expired when July 1, 2010 in Coordinated Universal Time arrives. In this case, the leap second information management unit 31b switches the leap second valid flag from a value indicating “valid” to a value indicating “invalid”. By referring to the value of the leap second valid flag, the leap second information management unit 31b determines whether or not the leap second correction value LS stored at the present time is valid.

  In this example, when the leap second correction value LS can be received from the GPS satellite by the satellite signal receiving unit 31a, the leap second information management unit 31b transmits the leap second transmitted from the GPS satellite together with the leap second correction value LS. The expiration date information may be updated with reference to the adjustment advance notice information. That is, if the leap second adjustment notice information indicates a future date and time, the month corresponding to that date is set as the expiration month. By doing so, the leap second information management unit 31b refers to the information of the expiration date and refers to the information on the expiration date regardless of whether the leap second correction value LS has been successfully received in the past. It can be determined whether the value LS is valid. In this case, when the leap second adjustment advance notice information indicates a past date and time (that is, when the next leap second adjustment execution timing is still unknown), the leap second information management unit 31b manually sets the leap second correction value LS. The expiration date information may be updated according to the same rule as that updated in step (b).

  As another example of the leap second expiry date management method, when the leap second correction value LS is set to expire on the last day of the month in which the leap second correction value LS is manually updated, the leap second information management unit 31 b There is no need to keep. In this case, the leap second information management unit 31b manages the expiration date using only the leap second validity flag as the leap second validity period information. That is, when the leap second correction value LS is manually updated, the leap second valid flag is set to “valid”, and when the first day of every month comes, the leap second valid flag is changed to “invalid”. Thereby, the leap second correction value LS updated in the previous month can be invalidated at the beginning of each month.

  In this example, the leap second information management unit 31b manages the expiration date depending on whether the previous leap second correction value LS has been updated manually or by reception of a satellite signal. May be changed. Specifically, the leap second information management unit 31b further holds flag information indicating whether or not the previous leap second correction value LS has been manually updated in the RAM 33, and when the first day of every month comes On the other hand, if it is determined from the flag information that the previous update was manually performed, the leap second valid flag is changed to “invalid”. On the other hand, when it is determined that the previous update was performed not by manual operation but by reception of satellite signals, for example, the leap second valid flag is set based on leap second adjustment advance notice information received together with the leap second correction value LS as in the above-described example. Update.

  As yet another example of the leap second expiry date management method, the leap second information management unit 31b uses a counter value indicating how long the leap second correction value LS is valid as the expiry date information. You may manage the expiration date of LS. This counter value is information representing the remaining period in which the leap second correction value LS is valid in predetermined time units such as hourly, daily, and monthly. As an example, when the expiration date of the leap second correction value LS is managed using a counter value in time units, the leap second information management unit 31b stores the counter value in advance when the leap second correction value LS is manually updated. Initialize with the specified value. For example, if the expiration date of the leap second correction value LS is 30 days, the counter value is set to 720 (= 30 × 24). Thereafter, the leap second information management unit 31b updates the counter value to a value obtained by subtracting 1 every time 1 hour elapses. As a result, the counter value gradually decreases with time and finally becomes 0 after 720 hours. After the counter value reaches 0, the leap second information management unit 31b does not perform any further process to decrease the counter value. If the counter value is 0, it is determined that the leap second correction value LS is not valid. In this example, the leap second information management unit 31b may change the leap second valid flag to “invalid” when the counter value reaches 0, or the counter value without using the leap second valid flag. Whether or not the leap second correction value LS is valid may be determined based on whether or not is 0. Also in this case, when the leap second correction value LS is updated by receiving the satellite signal, the next leap second adjustment execution timing is determined based on the leap second adjustment notice information received together with the leap second correction value LS. The counter time may be set according to the calculated value.

  Next, an example of an operation procedure when the radio timepiece 1 updates the leap second correction value LS will be described with reference to FIGS. 5 and 6. FIG. 5 is a state transition diagram of the radio timepiece 1 when leap second information update processing is performed, and FIG. 6 is an explanatory diagram showing a change in display state on the dial 53.

  First, as shown in FIG. 6A, in the normal time display state M1 in which the current date and time are displayed by the hands 52, the user performs an operation of pressing the first operation button S1. Then, the radio timepiece 1 transits to the leap second valid display state M2, and displays whether or not the leap second correction value LS currently held is valid. Specifically, when it is determined that the leap second correction value LS is valid by the above-described processing, as shown in FIG. 6B, the second hand 52c is “LS−” between the 11 o'clock direction and the 12 o'clock direction. Move to a position indicating “OK” and stop. On the other hand, when the leap second information management unit 31b determines that the leap second correction value LS is not valid, as shown in FIG. 6 (c), the second hand 52c moves to “LS-NG between 10 o'clock direction and 11 o'clock direction. To the position indicating "" and stop.

  When the user presses the first operation button S1 again in the leap second valid display state M2, the radio timepiece 1 returns to the time display state M1 and returns the second hand 52c to a position corresponding to the current time. When the leap second correction value LS is valid, there is no need to update the leap second correction value LS, so the user only has to press the first operation button S1 to return the radio timepiece 1 to the time display state M1. Note that, after the transition to the leap second valid display state M2, the radio timepiece 1 automatically returns to the time display state M1 even when the user does not perform any operation for a predetermined time. On the other hand, when the expiration date of the leap second correction value LS has expired, the user presses the second operation button S2 to cause the radio timepiece 1 to receive leap second information, or performs an operation of pulling out the crown S3. Select whether to update leap second information manually.

  When the user presses the second operation button S2 in the leap second valid display state M2, the radio timepiece 1 transits to the leap second reception state M3. In this state, the satellite signal receiving unit 31a attempts to receive the satellite signal including the leap second correction value LS transmitted from the GPS satellite. At this time, as shown in FIG. 6D, the radio timepiece 1 moves the second hand 52c to a position indicating the “RX” marker in the 12 o'clock direction in order to notify the user that reception processing is being performed.

  Thereafter, when reception of the leap second correction value LS is successful, the leap second correction value LS received by the leap second information management unit 31b is stored in the RAM 33, the expiration date of the leap second correction value LS is reset, and the time correction unit The time correction processing is performed using the leap second correction value LS newly received by 31c. Then, the radio timepiece 1 moves the second hand 52c to a position indicating “LS-OK” as shown in FIG. 6E to indicate to the user that the leap second correction value LS has been successfully received. Stop it once. Thereafter, the radio timepiece 1 automatically returns to the time display state M1 shown in FIG. 6 (f) (without operation by the user).

  On the other hand, when reception of the leap second correction value LS fails, the radio timepiece 1 returns to the time display state M1 without updating the leap second correction value LS. In FIG. 6, when reception of the leap second correction value LS fails, the time display state M1 is immediately restored. However, as in the case of successful reception of the leap second correction value LS, the leap second correction value is determined. In order to indicate that the reception of the LS has failed, the second hand 52c may be once moved to the “LS-NG” position and then returned to the time display state M1. Alternatively, when the radio timepiece 1 fails to receive the leap second correction value LS, the radio timepiece 1 does not return to the time display state M1, but shows that the expiration date of the leap second correction value LS remains expired. It is good also as returning to the leap second effective display state M2 as shown in (c).

  In the leap second valid display state M2, when the user performs an operation of pulling out the crown S3, the radio timepiece 1 transits to the leap second manual correction state M4. In this state, as shown in FIG. 6G, the leap second information management unit 31 b displays a numerical value corresponding to the leap second correction value LS stored in the RAM 33 on the time display unit 51. In the example of FIG. 6G, the leap second correction value LS is displayed by moving the hour hand 52a to a position corresponding to the leap second correction value LS. In this case, the second hand 52c points to the 11 o'clock direction between “LS-OK” and “LS-NG” in order to indicate that it is in the leap second manual correction state M4. When the user rotates the crown S3 in this state, the leap second information management unit 31b rotates the hour hand 52a according to the rotation direction and the rotation amount. At this time, the user moves the hour hand 52a to a position corresponding to the leap second with reference to the current leap second information published on a homepage on the Internet, for example. Then, when the user finally pushes the crown S3 back to the normal position, the leap second information management unit 31b determines that the correction of the leap second correction value LS by the user is completed, and the position of the hour hand 52a at that time The leap second correction value LS is updated to a value according to. Thereafter, the radio timepiece 1 automatically returns to the time display state M1 through the display of FIG. 6 (e), as in the case of successful reception of leap seconds in the leap second reception state M3.

  Here, the display method illustrated in FIG. 6G is merely an example, and the leap second information management unit 31b may display a numerical value corresponding to the leap second correction value LS by other methods. For example, in FIG. 6G, a numerical value is displayed according to the position of the hour hand 52a, but this numerical value may be displayed according to the position of the minute hand 52b. In the above example, the operating state of the radio-controlled timepiece 1 is indicated by the second hand 52c pointing to a marker such as “LS-OK”, “LS-NG”, “RX”. In the case of using the second hand, a numerical value corresponding to the leap second correction value LS may be displayed using the second hand 52c. Further, the leap second information management unit 31b may display a numerical value corresponding to the leap second correction value LS by a combination of two or more of the hour hand 52a, the minute hand 52b, and the second hand 52c. In this case, for example, the leap second information management unit 31b displays a numerical value by controlling a plurality of hands 52 (for example, the hour hand 52a and the minute hand 52b) to point to the same position. By doing so, it is possible to clearly indicate to the user that a numerical value corresponding to the leap second correction value LS is displayed instead of the normal time display.

  In the leap second manual correction state M4, the leap second information management unit 31b may display the numerical value of the leap second correction value LS as it is, but by adding or subtracting a predetermined numerical value to this value. A numerical value corresponding to the leap second correction value LS may be displayed. As described above, the GPS time information received by the radio-controlled timepiece 1 according to the present embodiment is shifted from the Coordinated Universal Time by an amount corresponding to leap seconds accumulated after January 1, 1980. As of January 1, 1980, there was a 19-second gap between International Atomic Time and Coordinated Universal Time. Therefore, there is always a difference of 19 seconds between the GPS time and the international atomic time, and the leap second correction value LS for adjusting the GPS time to the coordinated universal time also changes the international atomic time to the coordinated universal time. The value is 19 seconds smaller than the correction amount for matching. Therefore, the leap second information management unit 31 b may display a value obtained by adding 19 seconds to the leap second correction value LS on the time display unit 51. Specifically, in the example of FIG. 6G, when the leap second correction value LS is 15 seconds, the hour hand 52a points to a position corresponding to a value “34” obtained by adding 19 seconds to this. In this state, when the user rotates the crown S3 and moves the hour hand 52a, the leap second correction value LS is updated with a value obtained by subtracting 19 from the value indicated by the hour hand 52a. In this way, the user can change the value displayed on the time display unit 51 between the international atomic time and the coordinated universal time (accumulation of leap seconds) without being conscious of the deviation of the GPS time from the international atomic time. The leap second correction value LS can be updated to a value that allows the GPS time to be correctly corrected by changing to a numerical value that is generally disclosed as (value).

  Alternatively, the leap second information management unit 31b may display the leap second correction value LS as a relative value to the initial value (for example, the leap second correction value LS stored in the ROM 32 when the radio timepiece 1 is shipped). FIG. 7 shows a display example of a numerical value corresponding to the leap second correction value LS in such an example. In FIG. 7, the initial value of the leap second correction value LS is 15 seconds, and a value obtained by adding 19 seconds to this initial value (34 seconds) as in the case of FIG. An example of values is shown. A broken line in FIG. 7 indicates a reference value display position (hereinafter referred to as a reference position R). The numerical values around the dial 53 indicate the display positions of the numerical values that are +10 seconds, +20 seconds,..., 50 seconds, respectively, with respect to the reference value. However, in this example, the reference position R and the relative value with respect to the reference value are not actually displayed on the dial 53. In the example of FIG. 7, while the leap second correction value LS is 15 seconds to 40 seconds (that is, the display value on the dial 53 is 34 seconds to 59 seconds), the hour hand 52a is shown in FIG. The same position as in the case of. In the case of FIG. 6 (g), since it is an absolute value display, a value of 60 seconds or more cannot be displayed. However, in FIG. 7, the numerical value is displayed by the relative position with the position of 34 seconds as the reference position R. By operating the crown S3, it is possible to set a numerical value up to 74 seconds (up to 93 seconds as a display value on the dial 53) as the leap second correction value LS. The value of 93 seconds is a value corresponding to +59 seconds as a relative value with respect to the reference value of 34 seconds. In the example of FIG. 7, the hour hand 52a points to the 1 o'clock direction, which represents a display value of 65 seconds (+31 seconds with respect to the reference value of 34 seconds). According to the standard, leap seconds can be adjusted by adding and deleting leap seconds. However, in actual operation, leap seconds have not been deleted so far, and the cumulative value of leap seconds continues to increase. Yes. Therefore, for example, a value corresponding to the accumulated value of leap seconds at the time of shipment of the radio timepiece 1 is set as an initial value of the leap second correction value LS, and the leap second correction value LS is set only with a positive relative value to the initial value. There is no inconvenience. Note that setting the reference position R to 34 seconds is merely an example. For example, when the leap second correction value LS at the time of shipment is 26 seconds and a position of 45 seconds (9 o'clock direction) obtained by adding 19 seconds as an offset thereto is the reference position R, the displayable numerical range is 45 seconds. The leap second correction value LS in the range from 26 to 85 seconds can be set correspondingly. In any case, by displaying and setting the accumulated value of leap seconds as a relative value to the reference value, the accumulated value of leap seconds is 59 seconds at the maximum from the reference value (that is, seconds corresponding to one turn on the dial 53). The leap second correction value LS can be manually updated until it increases by several).

  In the state transition diagram of FIG. 5, when the second operation button S2 or the crown S3 is operated in the leap second valid display state M2, the state transits to the leap second reception state M3 or the leap second manual correction state M4, respectively. However, the leap second information management unit 31b may limit such state transition according to the determination result of whether the leap second correction value LS is valid. That is, the leap second information management unit 31b determines that the expiry date of the leap second correction value LS has expired, and only when it is displayed in the leap second valid display state M2, the leap second reception state M3 or the leap second reception state M3. When transition to the second manual correction state M4 is performed and it is determined that the expiration date of the leap second correction value LS has not expired, such transition is limited. In this way, when the leap second correction value LS is valid, the user can be prevented from updating the unnecessary leap second correction value LS.

  Although not shown in FIGS. 5 and 6, the radio timepiece 1 displays whether the TOW data can be received or the week number WN data can be received by the user's instruction operation. Also good. In addition, when the data of TOW and week number WN cannot be received, it may try to receive these data in accordance with the user's instruction operation, or the time and calendar may be corrected manually. .

  Here, control when the system of the radio timepiece 1 is restarted will be described. For example, when the power supply voltage of the power supply 40 decreases and it becomes difficult to continue the operation, the radio timepiece 1 saves the information in the RAM 33 in the non-volatile memory before the system down occurs. There is a case where a process for normally ending 30 is executed. In addition, a system reset of the control circuit 30 may be executed. When such processing is executed and then the control circuit 30 is restarted, the arithmetic unit 31 performs reacquisition of leap second information as part of the startup processing. Specifically, as shown in the state transition diagram of FIG. 5, when the radio timepiece 1 returns from the system reset state M5, the leap second reception state M3 or leap second manual operation is performed according to the state of the crown S3 at the time. Transition to one of the correction states M4. That is, when the crown S3 is not pulled out and is in the normal position (in the S3 off state), the state transits to the leap second reception state M3 and attempts to receive leap second information. On the other hand, when the crown S3 is pulled out (when the S3 is on), the state transits to the leap second manual correction state M4, and the leap second correction value LS is updated in accordance with the user's operation on the crown S3. When the radio timepiece 1 is restarted, if the radio timepiece 1 has been stopped for a long time before that, the leap second correction value LS is likely to have expired. Therefore, the radio timepiece 1 can acquire the latest leap second correction value LS information by performing such an update process at the time of restart. Note that when executing such a restart process, it is necessary to reacquire the TOW and week number WN data. The reception process for receiving such information from the GPS satellite may be executed before the reception process or manual update of the leap second correction value LS, or may be executed after that.

  In addition, the radio timepiece 1 does not immediately shift to the leap second reception state M3 or the leap second manual correction state M4 upon restarting, but refers to the leap second expiry date information at the previous system termination to determine the leap second correction value. It is determined whether the expiration date of the LS has expired, and only when it is determined that the expiration date of the leap second correction value LS has expired, the leap second reception state M3 or the leap second manual correction state M4 as described above is entered. Transitions may be made. In this case, the radio timepiece 1 first receives data of TOW and week number WN after restarting, and acquires information on the current date and time. Then, the current date and time information and leap second expiry date information are referred to determine whether the leap second correction value LS has expired. If the expiration date of the leap second correction value LS has not expired, the radio-controlled timepiece 1 transitions to the time display state M1 and starts normal time display.

  According to the radio-controlled timepiece 1 according to the present embodiment described above, the leap second can be manually set. Therefore, even when the leap second is not successfully received, the leap second information is acquired and the satellite signal is obtained. It can be used to correct the received time information. As described above, the transmission frequency of leap second information from a GPS satellite is lower than that of TOW and the like, and reception opportunities are limited. In particular, a portable watch such as a wristwatch may not be able to ensure a stable reception environment and may not be able to receive leap second information for a long time. In such a case, the radio timepiece 1 according to the present embodiment allows the user to manually set leap seconds as an alternative measure. In addition, when a leap second setting by the user is accepted, an expiration date is set for this leap second information, and when the expiration date expires, the fact is displayed to the user. The person can easily grasp whether or not the leap second information needs to be reset.

[Second Embodiment]
Next, a radio timepiece according to a second embodiment of the present invention will be described. The radio timepiece according to the present embodiment differs from the radio timepiece according to the first embodiment in its internal processing, but the hardware configuration and functional configuration may be the same as those in the first embodiment. Therefore, in the following, the same constituent elements as those in the first embodiment will be referred to by using the same reference numerals, and detailed description thereof will be omitted.

  In the present embodiment, the satellite signal receiving unit 31a acquires information on the TOW and week number WN included in the satellite signal, but does not receive information on the leap second correction value LS. The ROM 32 stores an initial value of the leap second correction value LS at the time of shipment, and the leap second information management unit 31 b first reads the initial value and stores it in the RAM 33. As in the case of the first embodiment, the leap second correction value LS stored in the RAM 33 is changed by manual update by the user. The time correction unit 31c corrects the GPS time obtained from the TOW to the time based on the Coordinated Universal Time using the leap second correction value LS stored in the RAM 33.

  Here, an example of an operation procedure when the radio timepiece 1 updates the leap second correction value LS in the present embodiment will be described with reference to FIGS. 8 and 9. FIG. 8 is a state transition diagram of the radio-controlled timepiece 1 when leap second information update processing is performed as in FIG. 5, and FIG. 9 is a diagram illustrating changes in the display state on the dial 53 as in FIG. FIG.

  First, as shown in FIG. 9A, in the normal time display state M1 in which the current date and time are displayed by the hands 52, the user performs an operation of pressing the first operation button S1. Then, the radio timepiece 1 transits to the leap second valid display state M2, and displays whether or not the leap second correction value LS currently held is valid. Specifically, when the leap second correction value LS is valid, as shown in FIG. 9B, the second hand 52c moves to a position indicating “LS-OK”, and when the expiration date has expired, FIG. As shown in c), the second hand 52c moves to a position indicating “LS-NG”.

  When the user presses the first operation button S1 in the leap second valid display state M2, or when a predetermined time has elapsed without any operation by the user, the radio timepiece 1 is set to the time as in the first embodiment. Return to the display state M1. On the other hand, when the expiration date of the leap second correction value LS has expired, the user manually updates the leap second information by performing an operation of pulling out the crown S3. Since the radio timepiece 1 according to the present embodiment does not support reception of leap second information, unlike the first embodiment, the second operation button S2 cannot be operated to shift to the leap second reception state M3. .

  When the user performs an operation of pulling out the crown S3 in the leap second valid display state M2, the radio timepiece 1 transitions to the leap second manual correction state M4. In this state, as shown in FIG. 9D, the leap second information management unit 31b moves the hour hand 52a to a position corresponding to the leap second correction value LS, thereby storing the leap second correction value stored in the RAM 33. A numerical value corresponding to LS is displayed. At the same time, the second hand 52c moves to a position indicating an intermediate position (11 o'clock direction) between “LS-OK” and “LS-NG”. When the user rotates the crown S3 in this state, the leap second information management unit 31b rotates the hour hand 52a according to the rotation direction and the rotation amount. Then, when the user finally pushes the crown S3 back to the normal position, the leap second information management unit 31b determines that the correction of the leap second correction value LS by the user is completed, and the position of the hour hand 52a at that time The leap second correction value LS is updated to a value according to. In FIG. 9, unlike the first embodiment, when the leap second correction value LS is manually updated, the radio-controlled timepiece 1 automatically displays FIG. 9A without the second hand 52 c indicating the “LS-OK” position. The time display state M1 as shown in FIG. However, as in the first embodiment, the display may return to the time display state M1 through the display as shown in FIG.

  As with the first embodiment, the radio timepiece 1 according to the present embodiment also transitions to the leap second manual correction state M4 when returning from the system reset state M5, depending on the state of the crown S3 at the time of the return. May be. In this case, as shown in the state transition diagram of FIG. 8, if the crown S3 is pulled out, the radio timepiece 1 transitions to the leap second manual correction state M4 when returning from the system reset state M5. On the other hand, when the crown S3 is in the normal state, unlike the first embodiment, the leap second information reception process is not executed in the present embodiment, so that the radio-controlled timepiece 1 transitions to the time display state M1. In any case, similarly to the first embodiment, the radio timepiece 1 needs to receive the data of TOW and week number WN from the GPS satellite when restarting. In particular, when the crown S3 is pulled out and shifts to the leap second manual correction state M4, the radio timepiece 1 does not receive the data of TOW and week number WN before shifting to the leap second manual correction state M4. However, it is preferable that the reception of these data is executed after the manual correction of the leap second is completed and the user returns the crown S3 to the normal state. This is because if the reception process is performed before the transition to the leap second manual correction state M4, the leap second cannot be manually corrected during the reception process, which causes the user to wait.

  According to the radio-controlled timepiece 1 according to the present embodiment described above, since the leap second reception process is not performed in the first place, it is not necessary to notify the user of an event such as a failure of the leap second reception. Can be made easier to understand. In addition, power consumption due to leap second reception processing can be avoided. On the other hand, even if it does not have a leap second reception function, by accepting manual leap second settings, when the leap second is adjusted, the time based on Coordinated Universal Time is reflected. can do. In addition, since the implementation frequency of leap second adjustment is not so high at present, even if the user manually sets the leap second, it does not require much time for the user.

[Modification]
Embodiments of the present invention are not limited to those described above. For example, in the above description, the radio timepiece 1 is a wristwatch, but other than this, various types of timepieces that receive a signal including time information from a satellite and correct the time may be used. In the above description, at least a part of the processing to be executed by the arithmetic unit 31 of the control circuit 30 may be realized by an arithmetic circuit such as an independent logic circuit.

  In addition, the display of whether or not the expiration date of the leap second correction value LS by the radio wave timepiece 1 according to the above-described embodiment has expired and the display mode of the numerical value according to the leap second correction value LS are merely examples. In addition, the radio timepiece according to the embodiment of the present invention may display such information in various display modes other than this. For example, when the expiration date of the leap second correction value LS has expired, the radio timepiece 1 may display the expiration date to the user by a method such as moving the hands for 2 seconds. Also, the instruction operation procedure by the user when performing leap second update processing may be various procedures other than those described above.

  Hereinafter, another display example when the radio timepiece 1 according to the embodiment of the present invention displays a numerical value corresponding to the leap second correction value LS in the leap second manual correction state M4 described above will be described. Hereinafter, a numerical value that is displayed and adjusted by the user in the leap second manual correction state M4 is referred to as an adjustment target value. As described above, the adjustment target value may be the leap second correction value LS itself, or a predetermined value (a value indicating a difference between GPS time and international atomic time, etc.) with respect to the leap second correction value LS. ) May be added.

  For example, the radio timepiece 1 may display the leap second correction value LS by a combination of the minute hand 52b and the second hand 52c. As a first specific example in this case, the radio-controlled timepiece 1 may indicate the value of the 1st place of the adjustment target value at the position of the second hand 52c and the value of the 10th place at the position of the minute hand 52b. FIG. 10 shows a display example in this case. In the example of FIG. 10, since the minute hand 52b points to the 3 o'clock direction and the second hand 52c points to the 4 o'clock direction, 34 seconds are displayed as the adjustment target value. The user can correct the leap second correction value LS by performing an operation of rotating the crown S3 in a state where such a display is made.

  At this time, the radio timepiece 1 may also display the value of the rollover counter according to the position of the hour hand 52a. Here, the value of the rollover counter indicates the number of times that the above-described week number WN overflows after a predetermined start time. The week number WN included in the information transmitted by the GPS satellite is 10-bit information, and its maximum value is 1023. Therefore, every time 1024 weeks (about 20 years) elapse, the week number WN overflows and is reset to zero. Therefore, the radio timepiece 1 may have a rollover counter function for counting the number of overflows. In this case, the radio timepiece 1 adds 1 to the value of the rollover counter when the week number WN overflows. Thereby, even if the radio timepiece 1 is used for a long period of 20 years or more, if the value of the rollover counter and the week number WN are combined, it is possible to determine how many weeks the current time corresponds from the predetermined start time. Know and can display calendar dates based on this information. In the display example of FIG. 10, the date display is performed by the date window 54 based on the calendar date obtained in this way. The radio timepiece 1 does not use the date window 54, but switches from the time display mode to the calendar display mode in accordance with an instruction from the user. In this calendar display mode, the calendar date is set using the pointer 52. It may be displayed.

  However, if the radio timepiece 1 having the rollover counter function is stopped for a long period of time including the timing when the week number WN overflows, the value of the rollover counter is counted up when the week number WN overflows. Therefore, there is a risk that the current week will be lost. Therefore, as shown in FIG. 10, the value of the rollover counter stored in the RAM 33 of the radio timepiece 1 is displayed and can be corrected by the user's operation input to cope with such a situation. Can do. In the example of FIG. 10, the hour hand 52 a indicates the 1 o'clock direction, which indicates that the value of the rollover counter is 1. In this state, for example, the user can change the value of the rollover counter by operating the first operation button S1.

  FIG. 11 shows a second specific example of the method of displaying the adjustment target value by the combination of the minute hand 52b and the second hand 52c. In this second specific example, the radio-controlled timepiece 1 rotates the minute hand 52b and the second hand 52c to the same position as when the time has advanced from the 0 minute 0 second per hour by the same number of seconds as the adjustment target value. That is, when the adjustment target value is less than 60 seconds, the radio timepiece 1 indicates the numerical value by the position of the second hand 52c. At this time, the minute hand 52b indicates a position of 0 minute (a position where the rotation angle from the 12 o'clock direction or the 12 o'clock direction is less than 6 degrees). When the adjustment target value is 60 seconds or more and less than 120 seconds, the minute hand 52b indicates the position of 1 minute (the position where the rotation angle from 12 o'clock is 6 degrees or more and less than 12 degrees), and the second hand 52c is adjusted. The position of the numerical value obtained by subtracting 60 from the target value is shown. In the example of FIG. 11, the minute hand 52b and the second hand 52c are moved to a position indicating the time of 1 minute 15 seconds, and this indicates that the adjustment target value is 75 seconds. In this example, the value of the rollover counter is not displayed at the same time as the adjustment target value, but is displayed depending on how many seconds the second hand 52c indicates in another correction state. Also in this example, similarly to FIG. 10, the date display is performed by the date window 54 based on the calendar date obtained by combining the value of the rollover counter and the information of the week number WN.

  Further, the radio timepiece 1 may display the adjustment target value using a pointer different from the hour hand 52a, the minute hand 52b, and the second hand 52c for time display. FIG. 12 shows a display example in this case. In this example, a first small hand 52d, a second small hand 52e, a third small hand 52f, and a fourth small hand 52g are arranged on the dial 53 in addition to the hour hand 52a, the minute hand 52b, and the second hand 52c. The first small hand 52d and the second small hand 52e are arranged so as to be rotatable about a common rotation axis on the 9 o'clock side of the dial 53, and the third small hand 52f and the fourth small hand 52g are arranged on the dial 53. It is arranged at the 3 o'clock side so as to be rotatable around a common rotation axis. The radio timepiece 1 displays the adjustment target value using these small hands in the leap second manual correction state M4. Specifically, the radio timepiece 1 displays an adjustment target value corresponding to the leap second correction value LS before the update by the first small hand 52d and the second small hand 52e, and the user uses the third small hand 52f and the fourth small hand 52g. The adjustment target value after adjusting by operating the crown S3 is displayed. The method of displaying the adjustment target value using two small hands may be the same as the method of displaying the adjustment target value by the combination of the minute hand 52b and the second hand 52c described above. When the user performs an operation of rotating the crown S3 in the leap second manual correction state M4, the positions of the first small hand 52d and the second small hand 52e are maintained, and only the third small hand 52f and the fourth small hand 52g are used by the user. Rotate according to the operation. Thereby, the user can adjust the leap second correction value LS in a state where the user can always confirm the adjustment target value before instructing the change.

  In the example of FIG. 12, the user operates the operation unit 60 to input the changed adjustment target value and applies the leap second correction value LS corresponding to the input adjustment target value (application time). ) Can also be entered. The radio timepiece 1 changes the leap second correction value LS corresponding to the input adjustment target value at a timing corresponding to the application time. Specifically, when receiving the input of the adjustment target value and the application time from the user, the radio timepiece 1 continues to use the leap second correction value LS before the input is received until the input application time arrives. When the input application time arrives, the old leap second correction value LS is overwritten with the leap second correction value LS corresponding to the adjustment target value received together with the application time. In this way, when the user announces the future leap second correction value LS, the user immediately instructs the radio timepiece 1 the leap second correction value LS to be changed in the future. A future time when the second correction value LS becomes valid can be indicated. For example, the radio timepiece 1 displays the update time with the hour hand 52a and the minute hand 52b. Specifically, in the example of FIG. 12, the hour hand 52a indicates the month of the update time, and the minute hand 52b indicates the date of the update time. In the figure, the hour hand 52a and the minute hand 52b indicate the time 7:01. Therefore, July 1 is set as the update time. In the leap second manual correction state M4, the user operates the first operation button S1 or the second operation button S2 by operating the adjustment target value, the month of the update time, and the day of the update time. And the value of each operation target is changed by operating the crown S3. In FIG. 12, the second hand 52c points to the 11 o'clock direction between “LS-OK” and “LS-NG” to indicate that the leap second manual correction state M4 is in effect.

  Further, when the radio timepiece 1 indicates that the leap second correction value LS is valid in the leap second valid display state M2, the time until which the leap second correction value LS is valid (that is, the leap second correction value LS is valid) When the time limit expires) may be displayed. In this case, the radio timepiece 1 performs a display as illustrated in FIG. 13 instead of the display of FIG. 6B or FIG. 9B described above. In FIG. 13, the hour hand 52a and the minute hand 52b indicate what month and day the expiration date expires. Here, similarly to the display of the update time in FIG. 12, the hour hand 52a indicates the month when the expiration date expires, and the minute hand 52b indicates the day. In FIG. 13, since the hour hand 52a and the minute hand 52b indicate the time of 1: 1, the currently stored leap second correction value LS is valid until the end of December and expires on January 1. Show. In FIG. 13, the second hand 52c points to “LS-OK” as in FIG. 6B and FIG. 9B.

  Furthermore, in the above description, in the states of FIG. 6B and FIG. 9B (the state in which the leap second correction value LS is shown to be valid), FIG. 6C and FIG. Unlike the state (state in which the leap second correction value LS is shown to be invalid), even if the user operates the crown S3, the user does not make a transition to the leap second manual correction state M4. Here, when the user performs an operation of pulling out the crown S3 in a state where the leap second correction value LS is valid, the radio timepiece 1 is set to the current setting instead of transitioning to the leap second manual correction state M4. Information related to the leap second correction value LS being displayed may be displayed. FIG. 14 is a display example in this case, and shows a display example when the crown S3 is operated in the state where the display of FIG. 13 is being performed. In this figure, as described with reference to FIGS. 10 and 11, the adjustment target value corresponding to the leap second correction value LS is displayed using the minute hand 52b and the second hand 52c, and the fifth small hand 52h and Information on the reception environment when the leap second correction value LS is received from the previous GPS satellite by the sixth small hand 52i is shown. Specifically, the fifth small hand 52h displays satellite number information indicating from which GPS satellites the leap second correction value LS information is received. The sixth small hand 52i displays information indicating in which region (city) the leap second correction value LS has been received. In this state, when the operation of pushing the crown S3 is performed, the radio timepiece 1 returns to the time display state M1. Here, information related to the leap second correction value LS is displayed when a predetermined operation is further performed in the state shown in FIG. 13, but the present invention is not limited to this. When the expiration date as shown in FIG. 13 is displayed, the satellite number information received or the city information received may also be displayed.

  DESCRIPTION OF SYMBOLS 1 Radio timepiece, 10 Antenna, 20 Reception circuit, 21 High frequency circuit, 22 Decoding circuit, 30 Control circuit, 31 Operation part, 31a Satellite signal reception part, 31b Leap second information management part, 31c Time correction part, 32 ROM, 33 RAM , 34 RTC, 35 Motor drive circuit, 40 Power supply, 41 Solar cell, 42 Switch, 50 Drive mechanism, 51 Time display section, 52 Pointer, 52a Hour hand, 52b Minute hand, 52c Second hand, 52d First small hand, 52e Second small hand, 52f 3rd small hand, 52g 4th small hand, 52h 5th small hand, 52i 6th small hand, 53 Dial, 54 day window, 60 operation part.

Claims (6)

A radio timepiece that receives a signal containing time information from a satellite and corrects the time,
Storage means for storing a leap second correction value used for correction of leap seconds with respect to the time information, and information regarding an expiration date of the leap second correction value;
A determination unit that determines whether or not the leap second correction value stored in the storage unit is valid using the information on the expiration date;
Determination result display means for displaying the determination result of the determination means;
A radio timepiece characterized by including. The radio timepiece according to claim 1,
A radio-controlled timepiece further comprising leap second display means for displaying a numerical value corresponding to the leap second correction value stored in the storage means. The radio timepiece according to claim 1 or 2,
The signal from the satellite includes leap second adjustment notice information,
A radio-controlled timepiece further comprising first management means for receiving a signal from a satellite including the leap second adjustment notice information and managing information on the expiration date based on the received signal. The radio timepiece according to any one of claims 1 to 3,
A radio-controlled timepiece further comprising second management means for determining whether or not June or December has passed and managing information related to the expiration date based on the determination result. The radio timepiece according to any one of claims 1 to 4,
A radio-controlled timepiece further comprising third management means for determining whether or not the first day of every month has arrived and managing information relating to the expiration date based on the determination result. The radio timepiece according to any one of claims 3 to 5,
The signal from the satellite includes information on the leap second correction value,
The radio-controlled timepiece receives a signal from a satellite including information on the leap second correction value, and changes the leap second correction value stored in the storage unit according to the received signal;
An instruction receiving means for receiving an instruction operation for changing the leap second correction value from a user;
A leap second correction value changing means for changing the leap second correction value stored in the storage means in response to the received instruction operation;
It is determined whether the leap second correction value stored in the storage means is changed according to a signal from the satellite, or whether the leap second correction value stored in the storage means is changed according to the received instruction operation. Changing means for changing a management method of information on the expiration date based on the determination result;
A radio-controlled timepiece characterized by further comprising:

Images